Genes for tRNAIle and tRNAAla in the spacer between the 16S and 23S rRNA genes of a blue-green alga: strong homology to chloroplast tRNA genes and tRNA genes of the E. coli rrnD gene cluster.

A 6.3 kbp Eco RI-Bam HI fragment which carries most of one of the two rRNA gene clusters of the blue-green alga Anacystis nidulans was cloned into plasmid pBR322. Sequence analysis of the spacer region between the 16S and 23S rRNA genes reveals the presence of genes for tRNAIle and tRNAAla. The 16S rRNA gene is separated from the tRNAIle gene by a 162 bp spacer which shows significant homology to the comparable region in Zea mays plastids. The spacer between the two tRNA genes is 33 bp long and can be folded into a 9 bp stem and loop structure. The 5' portion of the tRNAIle gene is 60% homologous to a "pseudogene"-like sequence which maps beyond the 5S rRNA gene.     

Genetic analyses of Dinophysis spp. support kleptoplastidy

The question of whether the toxin-producing and bloom-forming dinoflagellate genus Dinophysis contains plastids that are permanent or contains temporary so-called kleptoplastids is still unresolved. We sequenced plastid 16S rRNA gene, the complete trnA gene and the intergenic transcribed spacer region located between the trnA gene and the 23S rRNA gene, and performed diagnostic PCR on cells of the genus Dinophysis. Dinophysis spp. were collected from five different geographical regions: the Baltic Sea, the North Sea, the Greenland Sea and the Norwegian fjord Masfjorden. In most cases the sequence analysis showed that the sequences were identical to each other and to sequences from the cryptophyte Teleaulax amphioxeia SCCAP K0434, regardless of the place of sampling or the species analyzed. The exception was some cells of Dinophysis spp. from the Greenland Sea. These contained a 16S rRNA gene sequence that was more closely related to the cryptophyte Geminigera cryophila. The cells of Dinophysis contained either one of the 16S rRNA gene sequences or both in the same cell. Our results challenge the hypothesis that the plastids in Dinophysis are permanent and suggest that they are more likely to be kleptoplastids.     

Molecular cloning and comparative sequence analyses of rRNA operons in Streptomyces nodosus ATCC 14899.

The genome of Streptomyces nodosus contains six ribosomal RNA (rRNA) operons. Four of the rRNA operons; rrnB, rrnD, rrnE and rrnF were cloned. We have completely sequenced all four operons, including a region 750 base pairs (bp) upstream of the 16S rRNA gene. The three rRNA genes present in each operon were closely linked in the order 16S-23S-5S. A sequence comparison of the four operons showed more than 99% sequence similarity between the corresponding 16S and 23S rRNA genes, and more than 97% similarity between 5S rRNA genes. The sequence differences observed between 23S rRNA genes appeared to be localized in two specific regions. Substantial sequence differences were found in the region upstream of the 16S rRNA gene as well as in the internal transcribed spacers. No tRNA gene was found in the 16S-23S spacer regions.     

Plastid DNA in the mitochondrial genome of Oenothera: Intra- and interorganellar rearrangements involving part of the plastid ribosomal cistron

Summary Part of the plastid rRNA cistron is present in the mitochondrial genome of Oenothera. This sequence of 2081 nucleotides contains the 3 half of the plastid 23 S rRNA, the adjacent intergenic region and the 4.5 S rRNA. Secondary intramitochondrial sequence rearrangements involve this region of plastid origin and the gene encoding the putative mitochondrial small ribosomal protein S13. Sequence comparison suggests that the interorganellar transfer event occurred a long time ago. The mitochondrial sequence contains regions more homologous to the plastid DNA from tobacco than from Oenothera itself in the regions analysed, suggesting faster sequence evolution in plastids than in mitochondria of Oenothera.     

DNA sequence of the 16S rRNA/23S rRNA intercistronic spacer of two rDNA operons of the archaebacterium Methanococcus vannielii

The DNA sequence of the spacer (plus flanking) regions separating the 16S rRNA and 23S rRNA genes of two presumptive rDNA operons of the archaebacterium Methanococcus vannielii was determined. The spacers are 156 and 242 base pairs in size and they share a sequence homology of 49 base pairs following the 3' terminus of the 16S rRNA gene and of about 60 base pairs preceding the 5' end of the 23S rRNA gene. The 242 base pair spacer, in addition contains a sequence which can be transcribed into tRNAAla, whereas no tRNA-like secondary structure can be delineated from the 156 base pair spacer region. Almost complete sequence homology was detected between the end of the 16S rRNA gene and the 3' termini of either Escherichia coli or Halobacterium halobium 16S rRNA, whereas the putative 5' terminal 23S rRNA sequence shared partial homology with E. coli 23S rRNA and eukaryotic 5.8S rRNA.     

Identification of Escherichia coli through analysis of 16S rRNA and 16S-23S rRNA internal transcribed spacer region sequences

A bacterial strain, designated BzDS03 was isolated from water sample, collected from Dal Lake Srinagar. The strain was characterized by using 16S ribosomal RNA gene and 16S-23S rRNA internal transcribed spacer region sequences. Phylogenetic analysis showed that 16S rRNA sequence of the isolate formed a monophyletic clade with genera Escherichia. The closest phylogenetic relative was Escherichia coli with 99% 16S rRNA gene sequence similarity. The result of Ribosomal database project's classifier tool revealed that the strain BzDS03 belongs to genera Escherichia.16S rRNA sequence of isolate was deposited in GenBank with accession number FJ961336. Further analysis of 16S-23S rRNA sequence of isolate confirms that the identified strain BzDS03 be assigned as the type strain of Escherichia coli with 98% 16S-23S rRNA sequence similarity. The GenBank accession number allotted for 16S-23S rRNA intergenic spacer sequence of isolate is FJ961337.     

Analysis of 23S rRNA genes in metagenomes - a case study from the Global Ocean Sampling Expedition

As an evolutionary marker, 23S ribosomal RNA (rRNA) offers more diagnostic sequence stretches and greater sequence variation than 16S rRNA. However, 23S rRNA is still not as widely used. Based on 80 metagenome samples from the Global Ocean Sampling (GOS) Expedition, the usefulness and taxonomic resolution of 23S rRNA were compared to those of 16S rRNA. Since 23S rRNA is approximately twice as large as 16S rRNA, twice as many 23S rRNA gene fragments were retrieved from the GOS reads than 16S rRNA gene fragments, with 23S rRNA gene fragments being generally about 100 bp longer. Datasets for 16S and 23S rRNA sequences revealed similar relative abundances for major marine bacterial and archaeal taxa. However, 16S rRNA sequences had a better taxonomic resolution due to their significantly larger reference database.Reevaluation of the specificity of previously published PCR amplification primers and group specific fluorescence in situ hybridization probes on this metagenomic set of non-amplified 23S rRNA sequences revealed that out of 16 primers investigated, only two had more than 90% target group coverage. Evaluations of two probes, BET42a and GAM42a, were in accordance with previous evaluations, with a discrepancy in the target group coverage of the GAM42a probe when evaluated against the GOS metagenomic dataset.     

Discordant 16S and 23S rRNA gene phylogenies for the genus Helicobacter: implications for phylogenetic inference and systematics

Analysis of 16S rRNA gene sequences has become the primary method for determining prokaryotic phylogeny. Phylogeny is currently the basis for prokaryotic systematics. Therefore, the validity of 16S rRNA gene-based phylogenetic analyses is of fundamental importance for prokaryotic systematics. Discrepancies between 16S rRNA gene analyses and DNA-DNA hybridization and phenotypic analyses have been noted in the genus Helicobacter. To clarify these discrepancies, we sequenced the 23S rRNA genes for 55 helicobacter strains representing 41 taxa (>2,700 bases per sequence). Phylogenetic-tree construction using neighbor-joining, parsimony, and maximum likelihood methods for 23S rRNA gene sequence data yielded stable trees which were consistent with other phenotypic and genotypic methods. The 16S rRNA gene sequence-derived trees were discordant with the 23S rRNA gene trees and other data. Discrepant 16S rRNA gene sequence data for the helicobacters are consistent with the horizontal transfer of 16S rRNA gene fragments and the creation of mosaic molecules with loss of phylogenetic information. These results suggest that taxonomic decisions must be supported by other phylogenetically informative macromolecules, such as the 23S rRNA gene, when 16S rRNA gene-derived phylogeny is discordant with other credible phenotypic and genotypic methods. This study found Wolinella succinogenes to branch with the unsheathed-flagellum cluster of helicobacters by 23S rRNA gene analyses and whole-genome comparisons. This study also found intervening sequences (IVSs) in the 23S rRNA genes of strains of 12 Helicobacter species. IVSs were found in helices 10, 25, and 45, as well as between helices 31' and 27'. Simultaneous insertion of IVSs at three sites was found in H. mesocricetorum.     

Characterization of the rRNA genes of Ehrlichia chaffeensis and Anaplasma phagocytophila

The rRNA genes of Ehrlichia chaffeensis and Anaplasma phagocytophila have been analyzed. The 16S rRNA genes were previously characterized for both of these agents. Southern hybridization was used to show that there are single copies of both the 16S and 23S rRNA genes in the genomes of each organism, and that the 16S rRNA genes were upstream from the 23S rRNA genes by at least 16 and 11 Kb for E. chaffeensis and A. phagocytophila, respectively. PCR amplification and gene walking was used to sequence the 23S and 5S rRNA genes, and show that these genes are contiguous and are likely expressed as a single operon. The level of homology between the E. chaffeensis and A. phagocytophila 23S and 5S rRNA genes, and 23S-5S spacers, was 91.8, 81.5, and 40%, respectively. To confirm the hybridization data, genome walking was used to sequence downstream of the 16S rRNA genes, and although no tRNA genes were identified, open reading frames encoding homologues of the Escherichia coli succinate dehydrogenase, subunit C, were found in both E. chaffeensis and A. phagocytophila. Phylogenetic analysis using the 23S rRNA gene suggests that reorganization of the phylum Proteobacteria by division of the class Alphaproteobacteria into two separate subclasses, may be appropriate.     

Characterization of the 23S and 5S rRNA genes and 23S-5S intergenic spacer region (ITS-2) of Photobacterium damselae

The 23S ribosomal RNA (rRNA) gene has been sequenced in strains of the fish pathogens Photobacterium damselae subsp. damselae (ATCC 33539) and subsp. piscicida (ATCC 29690), showing that 3 nucleotide positions are clearly different between subspecies. In addition, the 5S rRNA gene plus the intergenic spacer region between the 23S and 5S rRNA genes (ITS-2) were amplified, cloned and sequenced for the 2 reference strains as well as the field isolates RG91 (subsp. damselae) and DI21 (subsp. piscicida). A 100% similarity was found for the consensus 5S rRNA gene sequence in the 2 subspecies, although some microheterogeneity was detected as inter-cistronic variability within the same chromosome. Sequence analysis of the spacer region between the 23S and 5S rRNA genes revealed 2 conserved and 3 variable nucleotide sequence blocks, and 4 different modular organizations were found. The ITS-2 spacer region exhibited both inter-subspecies and intercistronic polymorphism, with a mosaic-like structure. The EMBL accession numbers for the 23S, 5S and ITS-2 sequences are: P. damselae subsp. piscicida 5S gene (AJ274379), P. damselae subsp. damselae 23S gene (Y18520), subsp. piscicida 23S gene (Y17901), P. damselae subsp. piscicida ITS-2 (AJ250695, AJ250696), P. damselae subsp. damselae ITS-2 (AJ250697, AJ250698).     

A pseudogene cluster in the leader region of the Euglena chloroplast 16S-23S rRNA genes.

The nucleotide sequence of a region (leader region) preceding the 5'-end of 16S-23S rRNA gene region of Euglena gracilis chloroplast DNA was compared with the homologous sequences that code for the 16S-23S rRNA operons of Euglena and E. coli. The leader region shows close homology in sequence to the 16S-23S rRNA gene region of Euglena (Orozco et al. (1980) J. Biol.Chem. 255, 10997-11003) as well as to the rrnD operon of E. coli, suggesting that it was derived from the 16S-23S rRNA gene region by gene duplication. It was shown that the leader region had accumulated nucleotide substitutions at an extremely rapid rate in its entirety, similar to the rate of tRNAIle pseudogene identified in the leader region. In addition, the leader region shows an unique base content which is quite distinct from those of 16S-23S rRNA gene regions of Euglena and E. coli, but again is similar to that of the tRNAIle pseudogene. The above two results strongly suggest that the leader region contains a pseudogene cluster which was derived from a gene cluster coding for the functional 16S-23S rRNA operon possibly by imperfect duplication during evolution of Euglena chloroplast DNA.     

Nucleotide sequence of the single ribosomal RNA operon of pea chloroplast DNA

The nucleotide sequence of an 8 kbp region of pea ( Pisum sativum L.) chloroplast DNA containing the rRNA operon and putative promoter sites has been determined and compared to the corresponding sequences from maize, tobacco and the liverwort Marchantia polymorpha . The chloroplast DNA species of all vascular plants investigated, with the exception of a few legumes including pea, and of Marchantia contain an inverted repeat with an rRNA operon. The pea rRNA operon is the first sequenced rRNA operon from a plant with only one copy of the rRNA genes per molecule of chloroplast DNA. The organization of the operon is the same as for maize, tobacco and Marchantia . i.e. tRNA-Val gene/16S rRNA gene/spacer with intron-containing genes for tRNA-Ile and tRNA-Ala/23S rRNA gene/4.5S rRNA gene/5S rRNA gene. Current evidence suggests that the tRNA-Val gene may not be contranscribed with the other genes. For pea 16S, 23S, 4.5S and 5S rRNA have 1488, 2813, 105 and 121 nucleotides, respectively. The homologies of the entire operon (the tRNA-Val gene - 5S rRNA region) to those from tobacco, maize and Marchantia are 88, 82 and 79%, respectively. The corresponding homologies for tobacco/maize, tobacco/ Marchantia and maize/ Marchantia have similar values. The 16S and 23S rRNA genes from pea are more than 90% homologous to those from the 3 other species. We conclude that the fact that pea only has one set of rRNA genes per molecule of chloroplast DNA is apparently not correlated with any significant difference between the pea operon and the rRNA operons from tobacco, maize and Marchantia .     

Nucleotide sequence of the 235 rRNA from Haloferax mediterranei and phylogenetic analysis of halophilic archaea based on LSU rRNA

23S rRNA gene from the halophilic archaeon Haloferax mediterranei (strain ATCC 33500) was cloned and sequenced. Proceeding from the 2,912 nucleotides long sequence, the secondary structure of Haloferax genus large subunit rRNA was proposed. Haloferax mediterranei intergenic spacers 16S/23S and 23S/5S were also sequenced, and found to be 382 and 116 nucleotides long respectively. The 16S/23S spacer showed an Ala-tRNA intervening sequence, which is a common feature in Euryarchaeota. Sequence analysis of 23S rRNA and 16S rRNA was performed for the six organisms from the family Halobacteriaceae with both available gene sequences. Phylogenetic trees with completely different topology were obtained using both molecules.